Herbivore-induced volatile organic compounds (VOCs) are widely appreciated as an indirect defense mechanism since carnivorous arthropods use VOCs as cues for host localization and then attack herbivores. Another function of VOCs is plant–plant signaling. That VOCs elicit defensive responses in neighboring plants has been reported from various species, and different compounds have been found to be active. In order to search for a structural motif that characterizes active VOCs, we used lima bean (Phaseolus lunatus), which responds to VOCs released from damaged plants with an increased secretion of extrafloral nectar (EFN). We exposed lima bean to (Z)-3-hexenyl acetate, a substance naturally released from damaged lima bean and known to induce EFN secretion, and to several structurally related compounds. (E)-3-hexenyl acetate, (E)-2-hexenyl acetate, 5-hexenyl acetate, (Z)-3-hexenylisovalerate, and (Z)-3-hexenylbutyrate all elicited significant increases in EFN secretion, demonstrating that neither the (Z)-configuration nor the position of the double-bond nor the size of the acid moiety are critical for the EFN-inducing effect. Our result is not consistent with previous concepts that postulate reactive electrophile species (Michael-acceptor-systems) for defense-induction in Arabidopsis. Instead, we postulate that physicochemical processes, including interactions with odorant binding proteins and resulting in changes in transmembrane potentials, can underlie VOCs-mediated signaling processes

C. Kost

E. Almeras

G.-I. Arimura

I. T. Baldwin

J. Engelberth

J. Ruther

M. A. Farag

M. E. Maffei

M. Heil

Martin Heil

Ulrich Lion

V. Campanacci

Wilhelm Boland

English

PubMed

Springer - Publisher Connector

Defense-Inducing Volatiles: In Search of the Active Motif

Heil, M.

Lion, U.

Boland, W.

MPG.PuRe

RAPID COMMUNICATIONDefense-Inducing Volatiles: In Search of the Active MotifMartin Heil & Ulrich Lion & Wilhelm BolandReceived: 6 February 2008 /Accepted: 18 March 2008 /Published online: 12 April 2008# The Author(s) 2008Abstract Herbivore-induced volatile organic compounds(VOCs) are widely appreciated as an indirect defensemechanism since carnivorous arthropods use VOCs as cuesfor host localization and then attack herbivores. Anotherfunction of VOCs is plant–plant signaling. That VOCselicit defensive responses in neighboring plants has beenreported from various species, and different compoundshave been found to be active. In order to search for astructural motif that characterizes active VOCs, we usedlima bean (Phaseolus lunatus), which responds to VOCsreleased from damaged plants with an increased secretionof extrafloral nectar (EFN). We exposed lima bean to (Z)-3-hexenyl acetate, a substance naturally released fromdamaged lima bean and known to induce EFN secretion,and to several structurally related compounds. (E)-3-hexenyl acetate, (E)-2-hexenyl acetate, 5-hexenyl acetate,(Z)-3-hexenylisovalerate, and (Z)-3-hexenylbutyrate allelicited significant increases in EFN secretion, demon-strating that neither the (Z)-configuration nor the positionof the double-bond nor the size of the acid moiety arecritical for the EFN-inducing effect. Our result is notconsistent with previous concepts that postulate reactiveelectrophile species (Michael-acceptor-systems) for de-fense-induction in Arabidopsis. Instead, we postulate thatphysicochemical processes, including interactions withodorant binding proteins and resulting in changes intransmembrane potentials, can underlie VOCs-mediatedsignaling processes.Keywords Herbivore-induced volatiles . Hexenyl acetate .Indirect defense . Induced defense . Plant-plantcommunication . SignalIntroductionPlants respond to herbivore damage with the release ofvolatile organic compounds (VOCs) that signal the pres-ence of herbivore prey to predators and parasites andthereby serve as an indirect defense mechanism (e.g., Heil2008). Research has demonstrated that these VOCs can alsobe perceived by neighboring plants or intact, systemic partsof the damaged plant (Baldwin et al. 2006; Heil 2008).Particularly, green-leaf volatiles (GLVs) have been associ-ated with induced resistance in intact plants (Arimura et al.2000; Engelberth et al. 2004; Farag et al. 2005; Ruther andKleier 2005; Kost and Heil 2006;). However, little is knownabout the identity of VOCs that are active in this context orabout a structural motif that active VOCs might have incommon. In an attempt to explain the inducing activity ofsuch VOCs on gene expression, it has been suggested thatGLVs with an α,β-unsaturated carbonyl group such as (E)-2-hexenal can trigger defense responses in Arabidopsisthrough their activity as reactive electrophile species(Almeras et al. 2003).J Chem Ecol (2008) 34:601–604DOI 10.1007/s10886-008-9464-9M. Heil (*)Departamento de Ingeniería Genética, CINVESTAV,Km. 9.6 Libramiento Norte,Irapuato CP 36821( Guanajuato, Méxicoe-mail: mheil@ira.cinvestav.mxM. Heil :U. LionDepartment of General Botany, Plant Ecology,University of Duisburg-Essen,Universitätsstraße 5,45117 Essen, GermanyW. BolandDeparment of Bioorganic Chemistry,Max-Planck-Institute for Chemical Ecology,Hans-Knöll-Str. 8,07745 Jena, GermanyIn the present study, we used lima bean (Phaseoluslunatus L.) to search for traits that characterize defense-inducing VOCs. Lima bean responds to herbivore damagewith the jasmonate-mediated production of VOCs andextrafloral nectar (EFN), an aqueous, sugar-containingsecretion on nonreproductive plant organs that attractspredatory arthropods (mainly ants). The natural blend ofVOCs that is released from a herbivore-damaged lima beaninduces EFN secretion in intact neighboring plants (Kostand Heil 2006) and serves as a within-plant signal (Heil andSilva Bueno 2007). Among the quantitatively dominantVOCs that are released from induced lima bean, however,only (Z)-3-hexenyl acetate significantly induced EFNsecretion when used as pure compound (Kost and Heil2006). In the present study, we applied different structurallyrelated esters to lima bean plants and monitored their EFNsecretion.Materials and MethodsPlants were cultivated from seeds collected in the coastalarea of Puerto Escondido, Oaxaca, México (15°55.596 Nand 097°09.118 W, elevation 15 m). Seedlings werecultivated under ambient conditions in 250 ml pots filledwith soil from the original growing site. The plants werewatered daily and fertilized 6 weeks after germination withcommercial fertilizer: 10 ml per plant of a solution of 3 mgl−1 of “Fertilisante foliar de alta concentración” (GrupoBioquímico Mexicano, Aaltillo, Coah., Mexico). Experi-ments were conducted with plants of an age of 8–10 weeks.The following compounds were dissolved in Lanolin paste(all at 0.1 μg μl−1): (A) (Z)-3-hexenyl acetate, (B) (E)-3-hexenyl acetate, (C) (E)-2-hexenyl acetate, (D) 5-hexenylacetate, (E) (Z)-3-hexenyl isovalerate, (F) (Z)-3-hexenylbutyrate, (G) 2-ethylhexanol, (H) (E)-2-hexanal, (I) dec-anal, and (K) nonanal (Lanolin paste and all compoundswere purchased from Sigma Aldrich). Each 0.25 g paste perplant was applied on green plastic stripes (MAX Binde-band) attached to the plant in order to avoid direct contactof the paste with the plant. The plants were then packed inperforated PET foil bags (Bratenschlauch, Toppits, Minden,Germany) and in nets to protect them from EFN consumers.Amounts of VOCs released from the lanolin paste into theplants’ headspace under these conditions were monitored ina parallel experiment that used a closed-loop strippingsystem as described previously (Kost and Heil 2006). EFNsecretion was quantified from the five youngest leaves 24 hlater. In short, EFN concentration was measured with aportable refractometer, and nectar volume was measuredwith glass capillaries (Kost and Heil 2006) to calculate thetotal amount of soluble solids secreted, which in the case oflima bean EFN are mainly glucose, fructose, and sucrose.Leaves were then collected and dried to calculate EFNsecretion as soluble solids secreted per gram leaf dry massand per 24 h. Plants to which Lanolin paste without anycompound added had been applied served as controls(Lanolin control, LC). Per day, two groups each comprisingall 11 treatments were investigated, and in total eight plantsper treatment were used.Results and DiscussionAmounts of VOCs released from the lanolin paste into theplant’s headspace resembled those released from an inducedplant, i.e., all individual VOCs were present at 80–130% ofthe amount of (Z)-3-hexenyl acetate that is released undercomparable conditions from five induced leaves of limaFig. 1 EFN secretion in μg soluble solids secreted per gram leaf drymass and per 24 h is depicted. Plants were exposed for 24 h to (A) (Z)-3-hexenyl acetate, (B) (E)-3-hexenyl acetate, (C) (E)-2-hexenylacetate, (D) 5-hexenyl acetate, (E) (Z)-3-hexenyl isovalerate, (F) (Z)-3-hexenyl butyrate, (G) 2-ethylhexanol, (H) (E)-2-hexanal, (I) decanal,and (K) nonanal dissolved in Lanolin paste. Plants to which pureLanolin paste had been applied served as controls (LC). Lower andupper whiskers represent the 5% and the 95% percentile, lower andupper margins of boxes the 25% and the 75% percentile, the lineswithin boxes indicate medians. Different letters appearing aboveboxes mark treatment effects that differ significantly from each other(P<0.05 according to LSD posthoc analysis), and structures ofcompounds leading to a significant induction of EFN secretion ascompared to the control are graphically presented. LogP values of allcompounds were calculated with ChemDraw Ultra 6.0 and are givenunder the structures (compounds A–F) and in the insert (G–K)602 J Chem Ecol (2008) 34:601–604bean (data not shown, for amounts of VOCs released froman induced plant see Kost and Heil 2006). The differentVOCs to which lima bean plants had been exposed affectedtheir EFN secretion significantly (General linear model:F77,10=10.05, P<0.001). Compounds A–F consisted ofacyl hexenols in which the configuration and position of thedouble bond was systematically shifted from the polar headto the aliphatic terminus of the molecule. Moreover, theimportance of the size of the acyl moiety was evaluated byusing acetates, butyrate, and isovalerate of (Z)-3-hexenol.Although only one of the tested VOCs is naturally releasedfrom lima bean, exposure to the six compounds (A–F)elicited EFN secretions that were significantly higher thanthose of the controls (LSD posthoc analysis: P<0.05, seeFig. 1). These compounds were (Z)-3-hexenyl acetate, (E)-3-hexenyl acetate, (E)-2-hexenyl acetate, 5-hexenyl acetate,(Z)-3-hexenyl isovalerate, and (Z)-3-hexenyl butyrate.Hence, EFN secretion by lima bean can be induced byVOCs that are not released naturally from this species,while several VOCs that are released from induced plantsdid not significantly change EFN secretion in previousexperiments (Kost and Heil 2006).How are VOCs perceived by plants, and via whichmechanisms do they affect defense expression patterns? Ithas been suggested that molecules with an α,β-unsaturatedcarbonyl group can trigger defenses in Arabidopsis throughtheir activity as reactive electrophile species (Almeras et al.2003). In principle, VOCs could also be perceived bybinding to specific receptor-proteins or to odorant bindingproteins with a preference for a class of compounds, similarto animal olfactory systems.Apparently, neither the configuration nor the position ofthe double bound is a critical factor. Compounds reported toprime or induce gene activity or phenotypic defenses inintact corn plants comprise (Z)-3-hexen-1-ol, (Z)-3-hexenal,and (Z)-3-hexenyl acetate (Engelberth et al. 2004; Farag etal. 2005; Ruther and Kleier 2005). We found that (Z)-3-hexenyl acetate, (E)-3-hexenyl acetate, (E)-2-hexenyl ace-tate, and 5-hexenyl acetate all elicited particularly highEFN secretion rates in lima bean. The majority of thesesubstances lack an α,β-unsaturated carbonyl group, whichthus cannot be a generally required motif. In addition, acompound such as 5-hexenyl acetate cannot yield anelectrophile such as (E)-2-hexenal via the sequence of esterhydrolysis, oxidation, and isomerization, as it is principallypossible for (E or Z)-3-hexenyl acetate or (E or Z)-2-hexenyl acetate. Moreover, unlike (Z)-3-hexenyl acetate thepotential end product of the transformation sequence, (E)-2-hexenal, had only a weak effect on the nectar flow.Similarly, the observation that (Z)-3-hexenyl acetate and(E)-3-hexenyl acetate elicited almost identical EFN secre-tion rates contradicts the involvement of classical receptorproteins, since these usually require a specific stereochem-istry of the interacting molecule. We further calculatedLogP values to check for putative importance of thecompound’s lipophilicity but did not find any clear relationbetween the EFN-inducing activity of a compound and itsoctanol-water partition coefficient (Fig. 1).More studies are required to understand which VOCsinduce plant defenses via which mechanism. However, ourresults point to a new mechanism. Changes in transmem-brane potentials—occurring through modulations of ionfluxes—are involved in early signaling events in thecellular response to stress (Maffei et al. 2007), andexposition to VOCs indeed changes membrane potentialsin intact lima bean leaves (M. Maffei, personal communi-cation). It is thus tempting to speculate that the dissolvingof VOCs in the membranes coupled to interactions withmembrane proteins, similar to the odorant binding proteinsof insects (Campanacci et al. 2001), leads to changes intransmembrane potentials and thereby induces gene activ-ity. This hypothesis gains support from the observation thatthe induction of EFN secretion by VOCs appears to be agradual one rather than a clear ‘yes-or-know’ response.Several of the compounds that are released naturally fromlima bean showed a trend towards an increase in EFNsecretion, although the difference was not significant: EFNsecretion in response to Linalool was on average higher by40% than in control plants, and DMNT ((3E)-4,8-dime-thylnona-1,3,7-triene) increased EFN secretion by 50% (seeTable 1 in Kost and Heil 2006). Similarly, plants exposed toethylhexanol or (E)-2-hexanal in the present study showeda trend towards higher EFN secretions than controls(Fig. 1). EFN responds to a comparably wide variety ofstructures, and slight changes in the molecular structuregradually alter the induction effect. This observation is bestexplained by a comparably simple physicochemical pro-cess, whose detailed nature remains to be elucidated.How can signals evolve that apparently lack chemicalspecificity? The answer might be simply that plants seldomare exposed to GLVs or chemically related compounds thatare not released from attacked plants. In evolutionary terms,the probability of this situation was probably too low tocause any selection towards a more specific signalperception.Acknowledgments We thank Ralf Krüger, Susann Schiwy, and JuanCarlos Silva Bueno for help with the experiments and plantcultivation. Financial support by the DFG (grant He3169/4–2),CONACYT (Consejo National de Ciencias y Tecnologia) and theMax-Planck-Gesellschaft is gratefully acknowledged.Open Access This article is distributed under the terms of theCreative Commons Attribution Noncommercial License which per-mits any noncommercial use, distribution, and reproduction in anymedium, provided the original author(s) and source are credited.J Chem Ecol (2008) 34:601–604 603ReferencesALMERAS, E., STOLZ, S., VOLLENWEIDER, S., REYMOND, P., MENE-SAFFRANE, L., and FARMER, E. E. 2003. Reactive electrophilespecies activate defense gene expression in Arabidopsis. Plant J34:202–216.ARIMURA, G.-I., OZAWA, R., SHIMODA, T., NISHIOKA, T., BOLAND,W., and TAKABAYASHI, J. 2000. Herbivory-induced volatileselicit defence genes in lima bean leaves. Nature 406:512–515.BALDWIN, I. T., HALITSCHKE, R., PASCHOLD, A., VON DAHL, C. C.,and PRESTON, C. A. 2006. Volatile signaling in plant-plantinteractions: “Talking trees” in the genomics era. Science311:812–815.CAMPANACCI, V., KRIEGER, J., BETTE, S., STURGIS, J. N., LARTIGUE,A., CAMBILLAU, C., BREER, H., and TEGONI, M. 2001.Revisiting the specificity of Mamestra brassicae and Antheraeapolyphemus pheromone-binding proteins with a fluorescencebinding assay. J. Biol. Chem. 276:20078–20084.ENGELBERTH, J., ALBORN, H. T., SCHMELZ, E. A., and TUMLINSON, J.H. 2004. Airborne signals prime plants against insect herbivoreattack. Proc. Natl. Acad. Sci. USA 101:1781–1785.FARAG, M. A., FOKAR, M., ZHANG, H. A., ALLEN, R. D., and PARÉ, P.W. 2005. (Z)-3-Hexenol induces defense genes and downstreammetabolites in maize. Planta 220:900–909.HEIL, M. 2008. Indirect defence via tritrophic interactions. New Phytol178:41–61.HEIL, M., and SILVA BUENO, J. C. 2007. Within-plant signaling byvolatiles leads to induction and priming of an indirect plantdefense in nature. Proc. Natl. Acad. Sci. USA 104:5467–5472.KOST, C., and HEIL, M. 2006. Herbivore-induced plant volatiles inducean indirect defence in neighbouring plants. J. Ecol. 94:619–628.MAFFEI, M. E., MITHÖFER, A., and BOLAND, W. 2007. Before geneexpression: early events in plant-insect interaction. Trends PlantSci. 12:310–316.RUTHER, J., and KLEIER, S. 2005. Plant-plant signaling: Ethylenesynergizes volatile emission in Zea mays induced by exposure to(Z)-3-Hexen-1-ol. J. Chem. Ecol. 31:2217–2222.604 J Chem Ecol (2008) 34:601–604

Defence-inducing volatiles: in search of the active motif

RAPID COMMUNICATION
Defense-Inducing Volatiles: In Search of the Active Motif
Martin Heil & Ulrich Lion & Wilhelm Boland
Received: 6 February 2008 /Accepted: 18 March 2008 /Published online: 12 April 2008
# The Author(s) 2008
Abstract Herbivore-induced volatile organic compounds
(VOCs) are widely appreciated as an indirect defense
mechanism since carnivorous arthropods use VOCs as cues
for host localization and then attack herbivores. Another
function of VOCs is plant–plant signaling. That VOCs
elicit defensive responses in neighboring plants has been
reported from various species, and different compounds
have been found to be active. In order to search for a
structural motif that characterizes active VOCs, we used
lima bean (Phaseolus lunatus), which responds to VOCs
released from damaged plants with an increased secretion
of extrafloral nectar (EFN). We exposed lima bean to (Z)-3-
hexenyl acetate, a substance naturally released from
damaged lima bean and known to induce EFN secretion,
and to several structurally related compounds. (E)-3-
hexenyl acetate, (E)-2-hexenyl acetate, 5-hexenyl acetate,
(Z)-3-hexenylisovalerate, and (Z)-3-hexenylbutyrate all
elicited significant increases in EFN secretion, demon-
strating that neither the (Z)-configuration nor the position
of the double-bond nor the size of the acid moiety are
critical for the EFN-inducing effect. Our result is not
consistent with previous concepts that postulate reactive
electrophile species (Michael-acceptor-systems) for de-
fense-induction in Arabidopsis. Instead, we postulate that
physicochemical processes, including interactions with
odorant binding proteins and resulting in changes in
transmembrane potentials, can underlie VOCs-mediated
signaling processes.
Keywords Herbivore-induced volatiles . Hexenyl acetate .
Indirect defense . Induced defense . Plant-plant
communication . Signal
Introduction
Plants respond to herbivore damage with the release of
volatile organic compounds (VOCs) that signal the pres-
ence of herbivore prey to predators and parasites and
thereby serve as an indirect defense mechanism (e.g., Heil
2008). Research has demonstrated that these VOCs can also
be perceived by neighboring plants or intact, systemic parts
of the damaged plant (Baldwin et al. 2006; Heil 2008).
Particularly, green-leaf volatiles (GLVs) have been associ-
ated with induced resistance in intact plants (Arimura et al.
2000; Engelberth et al. 2004; Farag et al. 2005; Ruther and
Kleier 2005; Kost and Heil 2006;). However, little is known
about the identity of VOCs that are active in this context or
about a structural motif that active VOCs might have in
common. In an attempt to explain the inducing activity of
such VOCs on gene expression, it has been suggested that
GLVs with an α,β-unsaturated carbonyl group such as (E)-
2-hexenal can trigger defense responses in Arabidopsis
through their activity as reactive electrophile species
(Almeras et al. 2003).
J Chem Ecol (2008) 34:601–604
DOI 10.1007/s10886-008-9464-9
M. Heil (*)
Departamento de Ingeniería Genética, CINVESTAV,
Km. 9.6 Libramiento Norte,
Irapuato CP 36821( Guanajuato, México
e-mail: mheil@ira.cinvestav.mx
M. Heil :U. Lion
Department of General Botany, Plant Ecology,
University of Duisburg-Essen,
Universitätsstraße 5,
45117 Essen, Germany
W. Boland
Deparment of Bioorganic Chemistry,
Max-Planck-Institute for Chemical Ecology,
Hans-Knöll-Str. 8,
07745 Jena, Germany
In the present study, we used lima bean (Phaseolus
lunatus L.) to search for traits that characterize defense-
inducing VOCs. Lima bean responds to herbivore damage
with the jasmonate-mediated production of VOCs and
extrafloral nectar (EFN), an aqueous, sugar-containing
secretion on nonreproductive plant organs that attracts
predatory arthropods (mainly ants). The natural blend of
VOCs that is released from a herbivore-damaged lima bean
induces EFN secretion in intact neighboring plants (Kost
and Heil 2006) and serves as a within-plant signal (Heil and
Silva Bueno 2007). Among the quantitatively dominant
VOCs that are released from induced lima bean, however,
only (Z)-3-hexenyl acetate significantly induced EFN
secretion when used as pure compound (Kost and Heil
2006). In the present study, we applied different structurally
related esters to lima bean plants and monitored their EFN
secretion.
Materials and Methods
Plants were cultivated from seeds collected in the coastal
area of Puerto Escondido, Oaxaca, México (15°55.596 N
and 097°09.118 W, elevation 15 m). Seedlings were
cultivated under ambient conditions in 250 ml pots filled
with soil from the original growing site. The plants were
watered daily and fertilized 6 weeks after germination with
commercial fertilizer: 10 ml per plant of a solution of 3 mg
l−1 of “Fertilisante foliar de alta concentración” (Grupo
Bioquímico Mexicano, Aaltillo, Coah., Mexico). Experi-
ments were conducted with plants of an age of 8–10 weeks.
The following compounds were dissolved in Lanolin paste
(all at 0.1 μg μl−1): (A) (Z)-3-hexenyl acetate, (B) (E)-3-
hexenyl acetate, (C) (E)-2-hexenyl acetate, (D) 5-hexenyl
acetate, (E) (Z)-3-hexenyl isovalerate, (F) (Z)-3-hexenyl
butyrate, (G) 2-ethylhexanol, (H) (E)-2-hexanal, (I) dec-
anal, and (K) nonanal (Lanolin paste and all compounds
were purchased from Sigma Aldrich). Each 0.25 g paste per
plant was applied on green plastic stripes (MAX Binde-
band) attached to the plant in order to avoid direct contact
of the paste with the plant. The plants were then packed in
perforated PET foil bags (Bratenschlauch, Toppits, Minden,
Germany) and in nets to protect them from EFN consumers.
Amounts of VOCs released from the lanolin paste into the
plants’ headspace under these conditions were monitored in
a parallel experiment that used a closed-loop stripping
system as described previously (Kost and Heil 2006). EFN
secretion was quantified from the five youngest leaves 24 h
later. In short, EFN concentration was measured with a
portable refractometer, and nectar volume was measured
with glass capillaries (Kost and Heil 2006) to calculate the
total amount of soluble solids secreted, which in the case of
lima bean EFN are mainly glucose, fructose, and sucrose.
Leaves were then collected and dried to calculate EFN
secretion as soluble solids secreted per gram leaf dry mass
and per 24 h. Plants to which Lanolin paste without any
compound added had been applied served as controls
(Lanolin control, LC). Per day, two groups each comprising
all 11 treatments were investigated, and in total eight plants
per treatment were used.
Results and Discussion
Amounts of VOCs released from the lanolin paste into the
plant’s headspace resembled those released from an induced
plant, i.e., all individual VOCs were present at 80–130% of
the amount of (Z)-3-hexenyl acetate that is released under
comparable conditions from five induced leaves of lima
Fig. 1 EFN secretion in μg soluble solids secreted per gram leaf dry
mass and per 24 h is depicted. Plants were exposed for 24 h to (A) (Z)-
3-hexenyl acetate, (B) (E)-3-hexenyl acetate, (C) (E)-2-hexenyl
acetate, (D) 5-hexenyl acetate, (E) (Z)-3-hexenyl isovalerate, (F) (Z)-
3-hexenyl butyrate, (G) 2-ethylhexanol, (H) (E)-2-hexanal, (I) decanal,
and (K) nonanal dissolved in Lanolin paste. Plants to which pure
Lanolin paste had been applied served as controls (LC). Lower and
upper whiskers represent the 5% and the 95% percentile, lower and
upper margins of boxes the 25% and the 75% percentile, the lines
within boxes indicate medians. Different letters appearing above
boxes mark treatment effects that differ significantly from each other
(P<0.05 according to LSD posthoc analysis), and structures of
compounds leading to a significant induction of EFN secretion as
compared to the control are graphically presented. LogP values of all
compounds were calculated with ChemDraw Ultra 6.0 and are given
under the structures (compounds A–F) and in the insert (G–K)
602 J Chem Ecol (2008) 34:601–604
bean (data not shown, for amounts of VOCs released from
an induced plant see Kost and Heil 2006). The different
VOCs to which lima bean plants had been exposed affected
their EFN secretion significantly (General linear model:
F77,10=10.05, P<0.001). Compounds A–F consisted of
acyl hexenols in which the configuration and position of the
double bond was systematically shifted from the polar head
to the aliphatic terminus of the molecule. Moreover, the
importance of the size of the acyl moiety was evaluated by
using acetates, butyrate, and isovalerate of (Z)-3-hexenol.
Although only one of the tested VOCs is naturally released
from lima bean, exposure to the six compounds (A–F)
elicited EFN secretions that were significantly higher than
those of the controls (LSD posthoc analysis: P<0.05, see
Fig. 1). These compounds were (Z)-3-hexenyl acetate, (E)-
3-hexenyl acetate, (E)-2-hexenyl acetate, 5-hexenyl acetate,
(Z)-3-hexenyl isovalerate, and (Z)-3-hexenyl butyrate.
Hence, EFN secretion by lima bean can be induced by
VOCs that are not released naturally from this species,
while several VOCs that are released from induced plants
did not significantly change EFN secretion in previous
experiments (Kost and Heil 2006).
How are VOCs perceived by plants, and via which
mechanisms do they affect defense expression patterns? It
has been suggested that molecules with an α,β-unsaturated
carbonyl group can trigger defenses in Arabidopsis through
their activity as reactive electrophile species (Almeras et al.
2003). In principle, VOCs could also be perceived by
binding to specific receptor-proteins or to odorant binding
proteins with a preference for a class of compounds, similar
to animal olfactory systems.
Apparently, neither the configuration nor the position of
the double bound is a critical factor. Compounds reported to
prime or induce gene activity or phenotypic defenses in
intact corn plants comprise (Z)-3-hexen-1-ol, (Z)-3-hexenal,
and (Z)-3-hexenyl acetate (Engelberth et al. 2004; Farag et
al. 2005; Ruther and Kleier 2005). We found that (Z)-3-
hexenyl acetate, (E)-3-hexenyl acetate, (E)-2-hexenyl ace-
tate, and 5-hexenyl acetate all elicited particularly high
EFN secretion rates in lima bean. The majority of these
substances lack an α,β-unsaturated carbonyl group, which
thus cannot be a generally required motif. In addition, a
compound such as 5-hexenyl acetate cannot yield an
electrophile such as (E)-2-hexenal via the sequence of ester
hydrolysis, oxidation, and isomerization, as it is principally
possible for (E or Z)-3-hexenyl acetate or (E or Z)-2-
hexenyl acetate. Moreover, unlike (Z)-3-hexenyl acetate the
potential end product of the transformation sequence, (E)-2-
hexenal, had only a weak effect on the nectar flow.
Similarly, the observation that (Z)-3-hexenyl acetate and
(E)-3-hexenyl acetate elicited almost identical EFN secre-
tion rates contradicts the involvement of classical receptor
proteins, since these usually require a specific stereochem-
istry of the interacting molecule. We further calculated
LogP values to check for putative importance of the
compound’s lipophilicity but did not find any clear relation
between the EFN-inducing activity of a compound and its
octanol-water partition coefficient (Fig. 1).
More studies are required to understand which VOCs
induce plant defenses via which mechanism. However, our
results point to a new mechanism. Changes in transmem-
brane potentials—occurring through modulations of ion
fluxes—are involved in early signaling events in the
cellular response to stress (Maffei et al. 2007), and
exposition to VOCs indeed changes membrane potentials
in intact lima bean leaves (M. Maffei, personal communi-
cation). It is thus tempting to speculate that the dissolving
of VOCs in the membranes coupled to interactions with
membrane proteins, similar to the odorant binding proteins
of insects (Campanacci et al. 2001), leads to changes in
transmembrane potentials and thereby induces gene activ-
ity. This hypothesis gains support from the observation that
the induction of EFN secretion by VOCs appears to be a
gradual one rather than a clear ‘yes-or-know’ response.
Several of the compounds that are released naturally from
lima bean showed a trend towards an increase in EFN
secretion, although the difference was not significant: EFN
secretion in response to Linalool was on average higher by
40% than in control plants, and DMNT ((3E)-4,8-dime-
thylnona-1,3,7-triene) increased EFN secretion by 50% (see
Table 1 in Kost and Heil 2006). Similarly, plants exposed to
ethylhexanol or (E)-2-hexanal in the present study showed
a trend towards higher EFN secretions than controls
(Fig. 1). EFN responds to a comparably wide variety of
structures, and slight changes in the molecular structure
gradually alter the induction effect. This observation is best
explained by a comparably simple physicochemical pro-
cess, whose detailed nature remains to be elucidated.
How can signals evolve that apparently lack chemical
specificity? The answer might be simply that plants seldom
are exposed to GLVs or chemically related compounds that
are not released from attacked plants. In evolutionary terms,
the probability of this situation was probably too low to
cause any selection towards a more specific signal
perception.
Acknowledgments We thank Ralf Krüger, Susann Schiwy, and Juan
Carlos Silva Bueno for help with the experiments and plant
cultivation. Financial support by the DFG (grant He3169/4–2),
CONACYT (Consejo National de Ciencias y Tecnologia) and the
Max-Planck-Gesellschaft is gratefully acknowledged.
Open Access This article is distributed under the terms of the
Creative Commons Attribution Noncommercial License which per-
mits any noncommercial use, distribution, and reproduction in any
medium, provided the original author(s) and source are credited.
J Chem Ecol (2008) 34:601–604 603
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